Classifications

• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01F—MEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
  • G01F23/00—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm
  • G01F23/22—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water
  • G01F23/26—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water by measuring variations of capacity or inductance of capacitors or inductors arising from the presence of liquid or fluent solid material in the electric or electromagnetic fields
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01F—MEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
  • G01F23/00—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm
  • G01F23/22—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water
  • G01F23/24—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water by measuring variations of resistance of resistors due to contact with conductor fluid
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01F—MEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
  • G01F23/00—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm
  • G01F23/22—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water
  • G01F23/26—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water by measuring variations of capacity or inductance of capacitors or inductors arising from the presence of liquid or fluent solid material in the electric or electromagnetic fields
  • G01F23/263—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water by measuring variations of capacity or inductance of capacitors or inductors arising from the presence of liquid or fluent solid material in the electric or electromagnetic fields by measuring variations in capacitance of capacitors
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01F—MEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
  • G01F23/00—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm
  • G01F23/22—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water
  • G01F23/28—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water by measuring the variations of parameters of electromagnetic or acoustic waves applied directly to the liquid or fluent solid material
  • G01F23/284—Electromagnetic waves
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01F—MEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
  • G01F23/00—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm
  • G01F23/22—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water
  • G01F23/28—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water by measuring the variations of parameters of electromagnetic or acoustic waves applied directly to the liquid or fluent solid material
  • G01F23/284—Electromagnetic waves
  • G01F23/292—Light, e.g. infrared or ultraviolet
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01F—MEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
  • G01F23/00—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm
  • G01F23/22—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water
  • G01F23/28—Indicating or measuring liquid level or level of fluent solid material, e.g. indicating in terms of volume or indicating by means of an alarm by measuring physical variables, other than linear dimensions, pressure or weight, dependent on the level to be measured, e.g. by difference of heat transfer of steam or water by measuring the variations of parameters of electromagnetic or acoustic waves applied directly to the liquid or fluent solid material
  • G01F23/296—Acoustic waves
  • G01F23/2962—Measuring transit time of reflected waves
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01F—MEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
  • G01F25/00—Testing or calibration of apparatus for measuring volume, volume flow or liquid level or for metering by volume
  • G01F25/20—Testing or calibration of apparatus for measuring volume, volume flow or liquid level or for metering by volume of apparatus for measuring liquid level
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
  • G01N22/00—Investigating or analysing materials by the use of microwaves or radio waves, i.e. electromagnetic waves with a wavelength of one millimetre or more

Definitions

• the present invention relates to the field of metrology, and more particularly to a measuring device, a control device, a measuring device, a method for operating the measuring device, a computer-readable storage medium, a use of the measuring device for measuring the emulsion and a use of the measuring device for determining media properties.
• FMCW Frequency Modulated Continuous Wave
• Run-time method working level sensors are emitted electromagnetic or acoustic waves in the direction of a product surface. Following this, a sensor records the echo signals reflected from the filling material, the container fittings and the container itself and derives the respective filling level.
• the publication DE 10 2007 061 574 A1 describes a method for level measurement, in which a reflected portion of a signal and a capacitance between a capacitive probe and a reference electrode is measured. There may be a need to enable effective measurement, in particular of fill levels and limit levels as well as properties of a filling material.
• a measuring device in particular a measuring device for measuring fill levels and / or limit levels, may be used
• Control device a measuring device, a method for operating the measuring device, a computer-readable storage medium, the use of the measuring device for
• Emulsion measurement and the use of the measuring device for determining media properties are described.
• the invention may be described with the features of the independent claims. Other aspects may be indicated in the dependent claims.
• a measuring device which includes a first waveguide device having a first waveguide
• Wave guiding device can be used to perform a first measurement and the
• Measuring device may be configured to perform a second measurement.
• the first wave guiding device may also be arranged to divide a container interior into at least a first spatial region and a second spatial region.
• Electromagnetic wave in the first space area for example, a guided microwave, be set, which via the first coupling device in the first Waveguide may have been coupled.
• the first measurement it may be possible in one example to determine a fill level in the first spatial area.
• the measuring device may like to perform the second measurement on the first
• Waveguide device or be set up on at least a part of the first wave guiding device.
• the second measurement can be done in the second space area.
• the measuring device may be designed to measure a filling level.
• the measuring device in one example may also be an electromagnetic wave or generally any one
• Measuring device use an alternative measurement method, such as an acoustic, a conductive, a capacitive or inductive measuring method.
• the measuring signal which may use the measuring method of the measuring device. can over another
• the first wave guiding device may be arranged for spacing the first coupling device of the first wave guiding device and the measuring device, so that the first electromagnetic wave in the first spatial region can propagate at a predeterminable distance from the second spatial region provided for carrying out the second measurement with the measuring device.
• the first room area may be different from the second room area.
• the level may be determined at different locations with different methods of level measurement with a common measuring device.
• the space regions may be disjoint in one example. In another example, the two space regions may be substantially parallel to each other. The space regions may be disposed at different locations along a direction substantially perpendicular to a longitudinal axis of the first wave guide or perpendicular to a propagation direction of the first electromagnetic wave.
• the first wave guide may therefore both for spacing the
• Waveguide devices and / or the measuring device to be set up are examples of Waveguide devices and / or the measuring device to be set up.
• the measuring device may comprise a spacer device, wherein the spacer device for spacing the first coupling device of the first shaft guiding device and the
• the spacer may be configured to space the first waveguide and the measuring device, so that the first electromagnetic wave can propagate at a distance that can be predetermined by the distance device from the measuring device.
• Measuring device allow a level measurement within a container at different locations.
• the spacer device may additionally or alone provide for the separation of the spatial regions, so that it may be ensured that the first measurement essentially takes place in the first spatial region and the second measurement takes place essentially in the second spatial region.
• a control device may be provided.
• the control device may have an evaluation device, a first measuring device with a first connection device and a second measuring device with a second connection device. Furthermore, the control device may have a connection distance holding device and a collecting interface.
• the first measuring device and the second measuring device may be connected to the evaluation device and for providing a first electromagnetic wave via the first connection device or for providing a measurement signal for at least a part of the first wave guide device via the second
• the measurement signal can be provided to a Venness issued.
• the first terminal device may be spaced apart from the second terminal device by means of the terminal spacer means, so that the first electromagnetic shaft may be provided at a distance predeterminable by the terminal spacer device from the measurement signal.
• the first measuring device may be set up to determine and provide a first measured value of a measurement with the first electromagnetic wave in a first range, the provision of the first measured value to the evaluation device.
• the first electromagnetic wave may be provided for the first space area.
• the second measuring device may be used to determine and to provide a second one
• the second measured value may be the result of a measurement with the measuring signal in a second spatial region, wherein the second measured value may also be provided to the evaluating device.
• the evaluation device may, after receiving the first measured value and the second measured value for converting the first measured value and the second measured value into a common measured value and for
• a processing of the first measured value of a first measurement and a second measured value of a second measurement may take place in the evaluation device, wherein the evaluation may take place according to predefinable criteria.
• first measured value or as a second measured value can also be an echo curve or a
• Reflection signal can be provided.
• the echo curve can be generated from the reflection signal, and a measured value or a characteristic value for the corresponding spatial region can be determined from the echo curve.
• An echo curve can be the
• the underlying measuring method may be determined by the respective measuring device.
• Measuring device or the control device may be the type of connected
• the type of evaluation in particular the calculation method, may also be adjustable via an adjusting device on the control device.
• a measuring device for level measurement and / or for level measurement or limit value measurement may be described.
• the measuring device may be the measuring device according to the invention and the invention
• Have control device wherein the measuring device with the control device may be electrically and / or mechanically connected or connected.
• a mechanical connection may for example be made via a screw thread and / or a bayonet fitting.
• the measuring device and / or the control device may thus be suitable for level measurement or for limit level measurement.
• a method may be described which may serve to operate the measuring device according to the invention.
• the method may include providing a first electromagnetic wave in a first waveguide via a first connector.
• the first electromagnetic wave may be in a first spatial region of the first
• the method may include measuring at least a part of the first wave guiding device with a measuring signal which is provided via a second connecting device.
• the measuring of the first wave guiding device with the measuring device may take place in a second spatial region.
• the first connection means may be different from the second
• Connection device to be spaced with a connection distance holding device.
• the first electromagnetic wave and the measurement signal may be spatially separated for
• Measurement be provided. In essence, after performing the measurements, a first measurement of a measurement with the first electromagnetic wave may be sent to an evaluation device
• the first measured value and / or the second measured value may also be a determined echo curve in analog or digital form.
• the provided first and second measured values may be converted or combined in the evaluation device into a common measured value and this common measured value may be provided at a common interface of the evaluation device.
• the collection interface may in one example be an external one
• the evaluation device may also be part of an output unit.
• a computer-readable one may
• Storage medium may be stored on which may be stored a program code which, when executed by a processor, may instruct the processor to do so
• a program element may be described which, when executed by a processor, may instruct the processor to perform the inventive method.
• the control device may be realized as a single integrated circuit (IC).
• the use of the measuring device and / or the control device for determining media properties may be desirable be described, in particular of media properties of a liquid or a content of a container.
• measurements are carried out by means of at least two measurements taken substantially at a predeterminable distance
• Measurement results, levels or echo curves may be provided in the
• Measurement results may determine parameters with which a statement may be made that differs from a level. For example, such a statement may relate to the content or a mixing ratio of a content of a medium in a container. Also, a separation layer position can be determined. Furthermore, it may be possible to determine a characteristic value for an overlay medium, which is located above a filler surface and / or interface layer.
• An overlay medium may be a lighter second liquid that is above a first liquid, steam, a gas, or a gas mixture.
• a characteristic value may be a permeability, a permittivity, a pressure, a temperature or a saturation level of the overlay medium.
• the at least two measurements may be measurements according to different measurement principles. For example, a runtime or reflection measurement may be performed.
• a level measurement based on ultrasound, laser or electromagnetic wave may be performed. Furthermore, it may also be a level measurement using conductive, inductive or capacitive measurement are used. In particular, the level in a pipe can be determined by a conductive or capacitive measuring method.
• At least one transit time measuring method or reflection measuring method may be combined with any other measuring method for measuring.
• a runtime method may also be combined with another runtime measurement method. The difference of the measuring methods may be the place where the respective
• the measuring device may comprise a measuring device which may be selected from a group of measuring devices. the group consisting of a conductive measuring device, a capacitive measuring device, an inductive measuring device and an acoustic measuring device
• Measuring device may exist.
• the group also likes a second one
• Wavelining device and / or the second Wellenfiihr might be selected from a group of different wave guiding devices.
• Waveguide devices may consist of a coaxial conductor, a waveguide, a hollow conductor provided with at least one lateral opening, a guide device for a microwave, a standpipe, a wire, a metal rod and a cable.
• the first shaft guiding device and the measuring device, in particular the second shaft guiding device, may be combined in a common housing.
• the first wave guiding device may also be integrated in the measuring device or the sealing device in the first wave guiding device.
• a process connection may be an opening of a container. This opening may also be provided with a flange for mounting the measuring device and / or a control device.
• the common housing may facilitate easy transport of the measuring device.
• the measuring device may be a probe. Summing the components of the probe in a common housing may also facilitate mounting the probe to a controller. The distances of the channels may not be substantially affected during transport.
• the spacer means may comprise at least one spacer means selected from the group of
• the group of spacers may consist of a bracket, a flange, a container wall, a wall of a waveguide and an insulator.
• the spacer may like the first waveguide and the
• the same measure such as the level of a liquid in a container
• the location of the locations may be known essentially by the spacer.
• special le precautions such as side openings in a standpipe, it may be ensured that in the individual channels, a substantially equal level of liquid may be guaranteed.
• the first Wellenfiihr shark may be a metal rod and the measuring device, the outer wall of a waveguide.
• the metal rod may have a first longitudinal axis and the hollow conductor may have a second longitudinal axis, wherein in a coaxial arrangement, the longitudinal axes of
• the first one may
• Waveguide and / or second Wellenfiihr have an end, through this end a reference line substantially perpendicular to a
• Coupling device and the second coupling device are arranged in the substantially same distance with respect to this reference line.
• the reference line may be an imaginary reference line.
• the injectors may be at substantially the same distance from a pipe end or probe end.
• the first coupling device and / or the second coupling device may be at least one
• the group of launchers may consist of a stripline, a loudspeaker, an optical coupler, a laser, an inductive coupler, a capacitive coupler, a loop coupling, a pin coupling, and a pin hole coupling
• the coupling device may be suitable for a measuring signal, in particular a
• connection device in particular a first connection device or a second connection device
• connection devices may each have at least one
• Be terminal device which may be selected from the group of connection means consisting of a high-frequency connector, a high-frequency socket, a high-frequency adapter, a circulator and a directional coupler.
• the measuring device may be formed as a probe for a level gauge and / or for a Whitneystandsniess réelle.
• the probe may for example have a screw connection or a bayonet connection with which it can be connected to a suitable control device in order to form a measuring device or a field device, in particular a field device for the
• a measurement signal may be a current that may be adjusted depending on a capacitance or inductance.
• a measurement signal may be a second electromagnetic wave.
• the measurement of the first wave guiding device may thus be carried out essentially not only by means of a capacitive or inductive method, but also by means of a freely propagating or guided electromagnetic wave.
• an acoustic wave can also be used, for example in the ultra-sound range.
• the measuring device can thus have a further transit time measuring method or
• control device may include a common generator for generating the electromagnetic wave and the measurement signal and in particular the first electromagnetic wave and the second electromagnetic wave.
• control device may have a distribution device, wherein the distribution device for distributing the first electromagnetic wave to the first connection device and the second
• the electromagnetic wave may be adapted to the second terminal device.
• the measurement signal may be a current which may be influenced in accordance with a prevailing level.
• the method of operating the measuring device may include providing a second electromagnetic wave
• the second electromagnetic wave may be over the second
• Connection device can be provided. It may then be possible to provide a second measured value of a measurement with the second electromagnetic wave to the evaluation device.
• Fig. 1 shows a level measuring measuring device with a standpipe and a dipstick according to the guided microwave method for a better understanding of the present invention.
• Fig. 2 shows three evaluation curves for echo signal processing for a better understanding of the present invention.
• Fig. 3 shows a measuring arrangement with a measuring rod according to the principle of the guided microwave for a better understanding of the present invention.
• FIG. 4 shows an arrangement with a standpipe for level measurement after the free-radar radar principle for a better understanding of the present invention.
• FIG. 5 shows a measuring device for level measurement by means of a free-radiating electromagnetic wave and a guided microwave according to an exemplary embodiment of the present invention.
• Fig. 6 shows a measuring device for level measurement with two electromagnetic waves according to the principle of the guided microwave according to an exemplary
• FIG. 7 shows a further measuring arrangement for measuring a level with two electromagnetic waves according to the principle of the guided microwave according to an exemplary embodiment of the present invention.
• FIG. 8 shows a measuring arrangement for measuring an emulsion according to an exemplary embodiment of the present invention.
• FIG. 9 shows a measurement arrangement for determining media properties in the fill level measurement according to an exemplary embodiment of the present invention.
• FIG. 10A shows a simple block diagram of a control device according to an exemplary embodiment of the present invention.
• 10B shows a detailed block diagram of a separate signal path controller according to an exemplary embodiment of the invention.
• 1C shows a detailed block diagram of a control device having a common evaluation unit and a common output unit according to an exemplary embodiment of the present invention.
• Fig. 10D shows a detailed block diagram of a control device having a
• Analog switch according to an exemplary embodiment of the present invention.
• Fig. 10E shows a detailed block diagram of a control device having a
• High frequency switch according to an exemplary embodiment of the present invention.
• FIG. 11 shows a plan view of the measuring device of FIG. 6 according to an exemplary embodiment of the present invention.
• FIG. FIG. 12 shows a flowchart for a method of operating a measuring device according to an exemplary embodiment of the present invention.
• a measuring device may, for example, a first wave guide and a measuring device or a first wave guide and a second
• Have wave guiding device which are realized as two devices.
• the devices can use different measuring principles. With a standpipe, a microwave can be performed, but it can also measure a capacity of the standpipe.
• Level gauge or the control device generated signal generally free in the direction of the product surface to be measured.
• a device or a device which uses radar waves for measuring the product surface both a free propagation in the direction of the medium to be measured, which is the
• Radarvvellen from the level gauge in particular from the control device or the coupling device leads to the medium.
• the high-frequency signals in the interior or along the surface of a waveguide to the medium out.
• Level gauge in particular for the control device of a level gauge or a field device.
• the non-reflected signal components penetrate into the medium, and propagate in accordance with the physical properties of the medium in this further Direction of the container bottom. At the bottom of the tank, these signals are reflected, and arrive after passage of the medium and the superimposed atmosphere or the
• the measuring device receives the signals reflected at different points and determines therefrom the distance to the medium according to a travel time measuring method.
• the specific distance to the product is provided to the outside via an external interface.
• the provision can be implemented in analog form, for example as a 4..20 mA signal on a 4..20 mA interface, or also in digital form, for example on a fieldbus.
• a fieldbus can be a HART * 'bus, a Profibus or Fieldbus Foundation TM fieldbus.
• a level measurement, interface measurement and / or emulsion measurement can be done in different ways.
• Level measurement, interface measurement and / or emulsion measurement at least have a measuring device and / or a control device which determines the level according to the principle of the guided microwave.
• a measuring device and / or a control device which determines the level according to the principle of the guided microwave.
• embodiment is also possible to realize a device that uses as a measuring principle in addition to the guided microwave or alternatively at least one acoustic measuring principle, an optical measuring principle, an inductive measuring principle, a capacitive measuring principle or a substantially free-radiating measuring principle.
• FIG. 1 shows an arrangement for level measurement according to the principle of a guided microwave.
• the arrangement of Fig. 1 uses a coaxial standpipe 1 04 with inner conductor for filling lstandsteil.
• the container 100 is filled up to a filling height d B - d L with a medium M 106 or a liquid 106.
• the filling level is calculated from a difference between two distances starting from a reference height, for example the location of the coupling of the microwave oven.
• the space above the liquid 1 07 is initially filled with a further medium, for example with air L.
• the liquid to be measured 106 and the superposition atmosphere 107 are essenl in the container interior.
• a guided on the principle of the guided microwave level gauge 101 generates in a control device 130 with Hi lfe a radio frequency unit 102 a
• Electromagnetic pulse 103 and couples it into a probe 1 04, which is formed in the dargestel in Fig. 1 arrangement as a waveguide 104, whereupon this pulse propagates approximately at the speed of light in the direction of the product surface 105 to be measured inside the waveguide 104.
• the illustrated waveguide 104 is designed in the present example in the form of a coaxial conductor. As a probe, however, any shape of a waveguide in question, ie in particular single-wire or multi-wire cables.
• the coaxial conductor 104 used for the filling has a tube which is provided at regular intervals with holes 11 in the tube wall. which allow penetration of the liquid 106 to be measured into the region between the outer conductor, for example the wall of the tube 104, and the inner conductor 120.
• the product surface 105 reflects a portion of the incoming signal energy, whereupon the reflected signal component along the waveguide 104 back to the
• the unreflected signal component penetrates into the liquid 106 and propagates therein at greatly reduced velocity along the waveguide 104.
• the velocity c medium of the electromagnetic wave 103 within the liquid 106 is determined by the material properties of the liquid 106:
• Level gauge 101 in particular to the control device 130. In the level gauge
• the incoming signals are processed by means of the radio-frequency unit 102, and transformed, for example, into a low-frequency intermediate frequency range (IF range).
• IF range low-frequency intermediate frequency range
• an analog-to-digital converter unit 109 A / D converter
• the analogue echo curves which are provided by the radio-frequency unit 102 are digitized and made available to an evaluation unit 110.
• the evaluation unit 1 10 analyzes the digitized echo curve, determined on the basis of the echoes contained therein according to predeterminable method that echo that was generated by the reflection at the Medgutober Structure 105.
• the evaluation unit 110 determines the substantially exact distance up to this echo.
• the substantially exact distance to the echo is corrected in such a way that influences of the superimposed gas atmosphere 107 on the propagation of the electromagnetic waves are compensated.
• the thus calculated, compensated distance to the product 1 13 is provided to an output unit 1 1 1, which the specific value according to the specifications the user further processed, for example by linearization, offset correction. Conversion into a filling level d B - d L.
• the prepared measured value is provided to an external communication interface 1 12 to the outside. Any interface may be used, in particular a 4..20mA current interface, an industrial fieldbus such as HART *, Profibus, Fieldbus Foundation TM (FF), or a computer interface such as RS232, RS485, USB (Universal Serial Bus). , Ethernet or FireWire.
• FIG. 2 illustrates steps that are used in the context of echo signal processing in the
• Evaluation unit 1 10 are used to compensate for the influences of various media. Parts of these steps can be used in the evaluation of echo signals.
• Curve 201 firstly shows the echo curve 204 detected by the analog-to-digital converter unit 109 over time and obtained from the reflection signals.
• the echo curve first contains the transmission dipulse 205.
• a first reflection 206 is detected at time t 0 , which detects caused by the coupling of the high-frequency signal to the waveguide 104, for example from a coupling device.
• Another reflection 207 comes from the product surface 105 and is detected at time t L.
• the echo 208 generated by the lower end 108 of the waveguide 104 is finally detected at the time t B.
• the time-dependent curve 204 becomes a
• the distance-dependent curve 21 1 transformed.
• the ordinate of the first representation 201 is converted by multiplication with the speed of light in a vacuum into a distance axis of the second representation 202. This distance axis indicates the electrical distance.
• by offsetting an offset it is achieved that the echo 206 caused by the coupling in of the high-frequency signal receives the distance value 0m.
• the second representation 202 shows the echo curve 21 1 as a function of the electrical distance D.
• the electrical distance corresponds to the distance that covers an electromagnetic wave in a vacuum in a certain time.
• the electrical distance takes into account essentially no influences of a medium, which possibly lead to a slower preparation of the electromagnetic waves.
• the curve 21 1 therefore represents an uncompensated, but location-related echo curve.
• electrical distances may be denoted by capital letters D, whereas physical distances, which can be measured directly on the container, may be denoted by small letters d.
• the physical distance d L , d B , 113, 114 can be measured on the container.
• the echo curve 21 may also be possible to substantially completely compensate the echo curve 21 1, i. the echo curve is essentially completely physical
• the third representation 203 in FIG. 2 shows such a fully compensated echo curve 212 of the echo curve 21 1.
• the electrical distances of the abscissa are converted between 0 and D L into physical distance data according to the following relationship: i in this case represents a running index for the distance values between locations 0 and D L. Since e Lu f t and ⁇ ⁇ ⁇ ⁇ good approximation substantially correspond approximately to the value 1 must be made for this section in the present example, substantially no correction.
• the electrical distance data of the abscissa between D L and D B the one with that of air ⁇ ⁇
• ⁇ - M i represents a running index for distance values between the locations D L and D B.
• the third representation 203 of an echo curve shows the corrected course or the compensated course of the detected echo curve 204.
• Waveguide 104 generated echoes 21 0 are substantially in agreement with the detectable on the container 100 distances d L , d e , 1 1 3, 1 14 match.
• the conversion of the echo curve 21 1 into a compensated echo curve 212 is generally not carried out, since the correction of a single fill level value is sufficient. In other words, in the uncompensated curve 21 1, only the echo of the product surface 105 or the echo generated at the lower end of the waveguide may be compensated.
• Fig. 3 shows another arrangement 301 for level measurement according to the principle of the guided microwave.
• the level measurement is carried out in this arrangement with a single conductor 302.
• the device differs by a changed
• Level gauge 301 which instead of the coaxial conductor 104 as a probe 302 a
• Metal rod 302 for guiding a generated by the high-frequency unit 303 of the control device 330 high-frequency signal 103 uses. In other words, it likes that
• Level gauge 301 have a control device 330 and a probe 302.
• the high-frequency signal 103 can not propagate substantially inside the solid metal rod 302, but moves along the outer surface of the rod, in particular between rod and
• FIG. 4 shows a further device 401 for level measurement, which is designed according to the free-radiating radar principle.
• a standpipe 404 can be used to achieve a guidance of the Radarstiahlen or generally an electromagnetic wave.
• Radar principle may have the control device 430 for generating and evaluating a radar signal and the probe 404 or the standpipe 404.
• the fill level measuring device 401 emits the radar signal 402 via the coupling device 403 or antenna 403 into the interior of the standpipe 404, whereupon this radar signal propagates within the standpipe 404 in accordance with the physical laws. Operation without standpipe is also possible, in which case the free-radiating radar wave is guided essentially by the container inner wall.
• the arrangement according to FIG. 4 can also be used to detect the filling level with the aid of acoustic signals or optical signals in the standpipe.
• a multi-channel measuring device may be used.
• a multi-channel measuring device may have a multi-channel probe, a multi-channel probe
• a further parameter can be specified, such as a material characteristic or a mixing ratio of a medium.
• the measured value and / or parameter can be provided at a collection interface.
• the measuring device in particular the multi-channel measuring device or multi-channel probe, can be used for level measurement and / or interface measurement and / or
• Emulsions Little be used.
• the multi-channel measuring device 505 has a first channel 509, 510, 53 1 and a second channel 502, 504, 532.
• the level measuring device 501 is designed to generate an electromagnetic pulse 51 1 with the aid of a first measuring device 509 or by means of a first radio-frequency unit 509 and to couple this into the first waveguide 53 1, for example an outer side, with the aid of a suitable coupling 510 or a first coupling device 510 53 1 of the standpipe 505.
• the first coupling device 510 directs the electromagnetic pulse 51 1 or the electromagnetic wave 51 1 on the outside of the standpipe 505.
• the electromagnetic pulse 5 1 1 moves after coupling along the surface 531 of the standpipe 505 on and is reflected at the surface 506 of the medium to be veined.
• Radio-frequency unit 509 prepares an echo curve from the reflected signals, which is digitized in the analog-to-digital converter unit 507 and to the evaluation device
• the analog-to-digital converter unit 507 shares the first measuring device 509 and the second measuring device 502. i. the first measuring device 509 and the second measuring device 502 use a common A / D conversion unit 507.
• the evaluation unit 508 determines based on this digitized first echo curve at least one characteristic value for the level of the product surface 506.
• the level gauge 501 further radiates the radar wave 503 generated in the second measuring device 502, in the second channel 502 or in a second radio frequency unit 502 via a second coupling device 504 or antenna 504 into the interior of a
• Standpipe 505 from.
• the standpipe 505, in particular the inner tube wall of the standpipe 505, serves as a locally separate measuring device 532 and can as a second
• Waveguide 532 be executed for the radar shaft 503 or for the electromagnetic shaft 503. Due to the reflection on the product surface 506 is the
• Level measuring device 501 able to form a second echo curve, and digitize them using the analog-to-digital converter unit 507 and pass as a digital echo curve 204 to the evaluation device 508 or evaluation unit 508.
• Evaluation unit 508 determined on the basis of this digitized echo curve at least one further characteristic value for the level of Greinober Testing 506. It should be additionally noted that this determination of a level with the measuring device, for example, in the interior 532 of a standpipe 505, with
• measuring principles on which the Venness stimulate can be based are level measurements based on ultrasound or laser or even level measurements by means of conductive, inductive or capacitive measurement of the interior of the standpipe.
• the first wave guiding device 531 locally separates the judging means 532, so that the first measuring means 509 detects the filling material surface 506 at a different local position than the measuring means 532.
• the first wave guide 531 thus separates
• a probe 505 can provide two space regions 53 1, 532 in which measurements can be made.
• the evaluation unit 508 is capable of using at least one of the values for the level inside and / or outside the standpipe 505 determined beforehand from a first measurement and / or a second measurement
• Interfaces 513 is provided.
• the provision may be in analogue form
• a fieldbus can be a HART bus, a Profibus, or a Fieldbus Foundation TM fieldbus.
• the evaluation unit 508 determine extended information on the basis of the at least two measurements, that is to say information which is essentially no fill levels.
• extended information on the basis of the at least two measurements, that is to say information which is essentially no fill levels.
• these may be, for example, ASSET information, which provide early identification of imminent malfunctions of the sensor, or else information about the reliability of the measurement or the contamination of the standpipe.
• the standpipe 505 shown in Fig. 5 has a plurality of side openings 533 in the lateral surface of the standpipe 533, which allow a liquid to enter the interior 532 of the standpipe.
• the standpipe has a single lateral opening or exactly two lateral openings.
• at least one lateral opening is arranged on the standpipe 505 in such a way that, when installed, it is located in a container 100 as close as possible to the container bottom 534 and / or as far away as possible from the container bottom 534.
• Container bottom 534 may be referred to as the region in a container 100 on which
• the openings 533 may be designed as bores, fins or Schl itze.
• the openings may be distressed in a substantially uniform grid, along a line, or even irregularly along the length of the tube 505.
• the tube 505 has the openings on the two
• a tube may generally have openings at the end faces.
• a cover on a tube end face can be used as a spacer device. The spacer may be located at any position along the length of the tube.
• the measuring device 505 is designed as a multi-channel measuring probe 505. It has the spacer 535, which essentially ensures that the
• Measuring device 532 and the first wave guide 53 1 have a substantially constant distance over a predetermined length.
• the spacer device 535 may thus be set up so that it can enable a substantially parallel measurement in the two channels 5 1 1, 532. In the case that next to the first one
• Waveguide 532 also the measuring device 53 1 uses the propagation of an electromagnetic wave, the spacer may essentially ensure that the two waves propagate independently in a parallel direction. Thus, the measurement of the level 506 may occur at two different locations, the distance of which is substantially known.
• Spacer 535 may be adapted to a terminal spacer 535 'of the controller 530.
• For attaching the probe 505 to the control device 530 may at the
• Control device 530 a first terminal 536 'and a second
• Connection device 537 ' may be provided. At the measuring probe is a first
• Coupling device 510 with a connection device 536 and a second
• the first connector 536 ' may be for electrical connection to the connector
• the 536 of the first coupling device 5 10 may be provided, for example as a
• the second connection device 537 ' may be provided for electrical connection to the connection device 537 of the second coupling device 504, for example as a plug / socket combination.
• a plug / socket combination For mechanically connecting the measuring device 505 to the control device 530, a
• the mechanical coupling can also be effected by means of the spacer 535 or the terminal spacer 535 '.
• Terminal spacing means 535 ' may serve to connect the measuring signal or the electromagnetic wave of the control means 530 at a distance from the
• FIG. 6 shows a further arrangement 601 for multichannel level measurement.
• a coaxial conductor 605 is used as a multi-channel probe.
• a standpipe 605, 505 is provided with an inner conductor 603 and forms a Koaxialleiter 605, which is by attaching to the control device 630 part of the level gauge 601.
• the level 506 of the liquid inside this conductor 605 is determined by means of a second electromagnetic pulse 639 generated by the second measuring device 602, which is designed as a third radio-frequency unit 602. This third
• Radio frequency unit 602 is adapted to excite an electromagnetic wave in the coaxial conductor 605.
• the first measuring device 509 is the first one
• the first measuring device 509 is used to measure the level 506 of the liquid according to the method of measuring the level in FIG measure your first channel 531 along the outer surface of the standpipe 605.
• This embodiment of a two-channel measurement 53 1, 632 shown in FIG. 6 by means of a two-channel measuring probe 605 is also used to produce two independent measurements according to the principle of the guided microwave oven
• the guided wave propagates substantially between a potential and a reference potential.
• the rod may carry the potential and the reference potential may lie substantially at an infinitely distant point.
• the potential may be on the tube outer side 531 or lateral surface of the tube and the reference potential may lie on the inside of a container wall 538.
• a medium can be measured, which is located between the container wall 538 and the lateral surface 531 of the tube 505, 506.
• the potential on the inner conductor 603 and the reference potential may lie on an outer conductor, for example the outer surface of a tube 605, in particular the inner surface of a tube wall.
• the coupling devices 510, 504, 631 may be set up, a signal 5 1 1, 503, 603, which they via the connection means 536, 537, 636, 637 of
• the coupling device 510, 504, 631 may take care of this.
• the shafts 51 1, 639 can propagate in the desired areas, spatial regions 53 1, 532, 632 or channels.
• a first electromagnetic wave 51 1 may propagate in a first channel 531 and a second electromagnetic wave 639 in a second channel 632.
• the coupling device 510, 504, 631 may provide the assignment of the potential and the reference potential. For this assignment, the coupling device may have a potential separation.
• the coupling devices 510, 63 1 have the connection devices 636, 637. for the electrical Ankopphmg the probe 605 to the control device 630 on
• connection devices 636 ', 637' provide.
• the two channels 531, 632 are formed in the interior and exterior of the coaxial conductor 605, ie substantially between the standpipe 605 and the container wall 538 or. between inner conductor 631 and outer conductor 605.
• FIG. 7 shows another probe 733 according to an exemplary embodiment of the present invention.
• the fill level measuring device 701 in turn has two independent measuring devices 702, 703 or high-frequency units 702, 703, which are used to fill the level in two different ways 73 1. 732 or in two different channels 731, 732 or locally separated according to the principle of the guided microwave to eat.
• the local separation is along a radial direction of the coaxially arranged waveguides, i. essentially perpendicular to one
• Double coaxial conductor formed in which a coaxial conductor 708, comprising the standpipe 705 as outer conductor 705 and the rod 704 as an inner conductor 704, is surrounded by a waveguide 706, so that the coaxial conductor and the waveguide with respect to a longitudinal axis to each other are arranged substantially coaxially.
• the probe 733 thus has in
• the first measurement 731 uses the outer coaxial conductor 709 to determine a level value or level, with the outer coaxial conductor 709 carrying the
• Jacket tube 706 or standpipe 706 as an outer conductor and the tube 705 has an inner conductor.
• the second measurement 732 uses the inner coaxial conductor 708 for determination the filling level.
• the tube 706 of the outer coaxial conductor 709 forms the common housing of the probe 733.
• the first channel 73 1 and the second channel 732 divide the middle conductor 705 as the outer conductor 705 and the inner conductor 705
• Inner conductor 705 is used for the outer tube 706 or as outer conductor 705 for the inner conductor 704, depends on the wiring of the coupling device 734 of the outer conductor and the wiring of the coupling device 735 of the inner conductor.
• the middle conductor 705 may be multi-layered.
• the middle conductor may have a conductive outer conductor and a conductive inner conductor that penetrate through
• Dielectric are substantially isolated from each other to achieve both a local separation and an electrical separation.
• the outer conductor or the outside of the middle conductor 705 may be the inner conductor of the first channel 73 1 and the inner conductor or the inner side of the middle conductor 705 may also be the outer conductor of the second channel 732.
• the inner coaxial conductor 708 and the outer coaxial conductor 709 may be incorporated in FIG.
• Coaxial conductor 708 is a part of the tube wall of the sheath tube 706 shown in Fig. 7 by dashed lines.
• the open lower end faces of the tubes 705 and 708 at opposite the coupling means 734, 735 can be seen.
• the two regions which separate the probe 733 correspond to the two channels 731, 732, in each case between the inner conductor 704, 705 and outer conductor 706, 705.
• FIG. 8 shows a measuring device 801 for measuring separating layers and / or
• the measuring device 801 has the control device 830 and the probe 83 1.
• the probe 83 1 is set up such that a different liquid level is established in a second channel 832 than in a first channel 53 1.
• the structural design of the probe 831 with substantially only two lateral openings 834, 835 may prevent, for example, a sensor formed in the probe interior 832
• Such a trained probe 83 1 likes the use of the probe 83 1 for measuring the emulsion in a standpipe
• characteristic values can be determined from the at least two measurements in the two channels 53 1, 832 which are required in the course of the interface measurement and / or the emulsion measurement.
• Emulsions will be set up so that they can separate within a container two areas 531, 83 1 or channels 53 1, 83 1, wherein in one area a mixed emulsion of several liquids can be measured and in the other area caused by segregation separation between the liquids can be measured.
• An associated control device 830 can output a characteristic value for the emulsion via the collection interface 836.
• FIG. 9 shows a measuring device 901 for measuring or determining the
• the meter includes the probe 933 and the controller 930.
• the probe 933 or measuring device 933 is a waveguide 902 which in the interior at least partially filled with a
• Dielectric 903 has. The dielectric 903 is in an upper region of the
• the upper area is essentially enclosed by a container bottom 534 near the second coupling device 63 1 of a second channel 632, B.
• a first channel 5 1, A the outside of the waveguide 902 can be measured. Due to the different measurements in the two channels A, B, a media property of the overlay atmosphere 906 or the overlay liquid 906 may be determined.
• the dielectric 903 delays the propagation of the wave used for the measurement inside the probe 933. In this way, it is possible that the two signals in the two channels 63 1, 632 have different transit times, although the physical distance to the product 106 essentially the same.
• the collection interface 936 may output a characteristic value for the superimposing atmosphere 906 or superposition liquid 906 via the collection interface 936.
• a measuring device 501, 601, 701, 801, 901 occupies only a single one
• the combination of at least two channels or multiple channels in a single probe 733, 505, 605, 83 1, 902, in particular the combination of multiple channels in a common housing, for example by the spacer 535, 535 ", 635, 635 ', may make it possible in that the probe occupies only a single process opening of a container 100.
• a space-saving and compact arrangement of two measuring channels is possible
• Device 1010 for level measurement In order to adapt to the multiplicity of channels A, B, 531, 532, 632, 731, 732 or the at least two channels which the measuring device 505, 605, 933, 733 provides, a corresponding configuration of the device electronics can be carried out, which permits the operation of allows at least two channels of a probe.
• the connection means at the couplers 504, 5 10, 734, 735 of the probe or the probe connections may be indicated generally by the letters A and B, to indicate that they are two channels, but not to the type of
• the channels A, B may be kept at a distance by the terminal spacer, which may correspond to a distance of the associated terminals of the coupling devices.
• FIG. 10A shows that it is possible to combine two complete electronic inserts 1012, 1013 of two individual associated control devices of any two fill level measuring devices by means of the evaluation device 101 1 in order to arrive at a common characteristic value at the collection interface 1014.
• the individual measuring devices in particular the associated control devices, which work according to the single-channel principle, can also be used to operate the individual channels of a multichannel probe.
• the measuring device resp. an associated probe, which operates on the single-channel principle, essentially allows only the execution of a single measurement, since, for example, no further
• Coupling device may be provided for an additional measurement.
• Electronic inserts may therefore work according to different principles
• the higher evaluation unit 101 1 calculates the individual characteristic values provided by the electronics inserts 1012, 1013, which can be determined, for example, from measurements A and B carried out in parallel or in succession, and forms at least one common one Measured value provided at the common external interface 1014.
• This common measured value may be a characteristic value that is present in the
• Substantially only by performing at least two measurements can be determined, in particular a characteristic value which can be determined substantially only by performing at least two measurements at different locations.
• the characteristic value may essentially only be determined by carrying out two individual measurements for fill level measurement and / or greyscale measurement.
• FIG. 10B shows a block diagram of a control device 1020 in which the
• the measuring devices 1012b, 1013b can be individual fill level measuring devices, in particular their control device or evaluation electronics.
• the functionality of a control device 1020 according to FIG. 10B substantially corresponds to the functionality of the control device 1010 according to FIG. 10A, the construction or the electronics of the measuring device 1012, 1013 being shown in more detail.
• Measuring device 1012b comprises the high-frequency generation unit 1021, the analog-digital
• the second measuring device 1013b has the high-frequency generation unit 1022, the analog-to-digital converter unit 1024 and the evaluation unit 1026, which are set up to cooperate in such a way that they can perform a second measurement in the second measuring channel B in combination and a second measured value, eg
• the control device 1020 may have at least three external interfaces. In one example, the controller 1020 may only have 3 external interfaces. Two of the external interfaces 1001, 1002 may serve to provide a measurement signal and / or to receive a measurement signal
• Echo signal and the third may serve as a collection interface 1014 for providing a common measurement.
• the measured values in the two channels A, B are offset by a suitable program logic in the output unit 1027 and provided to the outside via the collection interface 1014.
• the output unit 1027, the first evaluation unit 1025 and the second evaluation unit 1026 may form a common evaluation unit or common evaluation device.
• the measurement with the second measuring device B can also be realized according to an alternative measuring principle, which differs from a guided or freely propagating electromagnetic wave.
• the radio frequency unit 1022 then has a suitable unit for generating the measurement signal, for example a laser generation unit, an optical signal source, an ultrasound generation unit, an acoustic signal source, a
• FIG. 1C shows another variant of a control device 1030.
• the first measuring device 101 is 2c and the second one
• the control device 1030 uses a common evaluation unit 1033 for the evaluation of the digitalized echo curves or measured values of the channels A and ⁇ , which are provided at the terminals 103 1 and 1032. Consequently, the evaluation unit 1033 has exactly three connections. With one connection is the
• Evaluation unit 1033 connected to the output unit 1 037, with the second Anschlus is the evaluation unit 1033 with the first channel A 1 012c and with the third Anschlus is the evaluation unit 1033 connected to the second channel B 1013c.
• the first measuring device 10 1 2 c and the second measuring device 1013 c share a common evaluation unit 1033 or evaluation device 1033.
• the first measuring device 1012d and the second measuring device 1013d form an A / D converter.
• the conversion of the signals of the two channels A, B into a digital representation can be carried out with a single analog-to-digital converter unit 1041 within the control device 1040.
• the control device 1040 on an analog switch 1042, which the analog and low-frequency signals of the channels A, B in one
• Time-division multiplexing method to the analog-to-digital converter unit 1041 forwards.
• the measurements in the two channels A, B are carried out in chronological succession because of the shared use of the A / D converter unit 1041. Therefore, the evaluation unit 1043 is in
• the evaluation unit 1043 receives the time division multiplex signal from the A / D converter 1041 via one connection. Via the other connection, it forwards a processed signal, which it has obtained from the measurement signals of the channels A, B, to the output unit 1037.
• FIG. 10E The block diagram of a control device 1050, a sensor or measuring device according to FIG. 10E shows a circuit arrangement in which the two measuring devices 1012e,
• Radio frequency unit 105 1 is a high-frequency switch 1052 is provided.
• Radio frequency unit 105 1 is a high-frequency switch 1052 is provided.
• the common housing of the control device may include the terminal spacer 1003, which may be the terminal means
• the channels A, B keeps at a certain distance from each other. This distance may match a probe to be operated with the respective control device. By providing different distances can be a
• Control device only the appropriate probes are used.
• the circuit arrangements of FIGS. 10A to 10E can be realized as an integrated circuit.
• connection device 1001, 1002 of the control device or as a connection device of the coupling device a 50 ohm coaxial cable may be provided.
• FIG. 1 1 shows a plan view of a measuring device 605 of FIG. 6, which operates on the two-channel principle.
• the measuring device has the standpipe 605, on which by means of the spacer 635 and / or the partition wall 1 100 two measuring channels 53 1, 632 are formed.
• the measuring channels 531, 632 are located inside and outside the standpipe 605.
• a measuring signal for example an electromagnetic wave, can be impressed into these measuring channels 531, 632 via the connecting devices 636, 637 of the coupling devices (not shown in FIG. 12).
• a measurement signal propagation in the channels 531, 632 takes place independently of one another, so that independently of one another a fill level can be measured at specific positions. From the locally different measurement results, other parameters can be derived in addition to the level.
• the Position of the measurements is essentially determined by the arrangement of
• FIG. 1 2 shows a flow chart for a method for operating a
• step S 2 the provision of a first electromagnetic wave in a first waveguide device 1 100 takes place via a first connection device 636.
• Step S3 provides for measuring at least a portion of the first one
• Waveguide 632 which has a second connection means 637 ', wherein the first connection means 636' from the second connection means 637 'with the terminal spacer 635' spaced apart.
• Terminal spacer 635 ' may be configured like the spacer 635 of the probe.
• the spacer device can also be formed by a common housing in which the control device is accommodated.
• a first measured value of a measurement with the first electromagnetic wave is provided to an evaluation device. This measured value is obtained from the evaluation of the echo curve of the first electromagnetic wave.
• step S5 the provision of a second measured value of a measurement with the sealing device 632 to the evaluation device takes place.
• the provision of the first measured value takes place before the second measured value is made available.
• the provision of the first measurement value occurs after the second measurement value has been provided.
• the provision of the first electromagnetic wave and the measuring signal of the measuring device 632 can take place in steps S2 and S3, respectively.
• step S6 the measurement results are summarized and / or evaluated.
• the first measured value and the second measured value are converted into a common measured value, and the common measured value is provided at a collecting interface of the evaluating device.
• a parameter of the filling material or of a container contents can also be provided via the collection interface, which differs from a filling level and, for example, a media property or a
• a device 501, 601, 701, 801. 901 for measuring a level, a separation layer or an emulsion according to a transit time method is provided, the device being a media-contacting standpipe 505, 605, 733 and a first evaluation unit 1025.
• the first evaluation unit 1025 is configured such that it can determine at least one characteristic value for a first fill level, a first separation layer and / or a first emulsion within the media-contacting standpipe 505, 605, 733, 83 1, 933.
• the device 501, 601, 701, 801, 901 also has a further evaluation unit, wherein the further evaluation unit 1026 is designed such that it has at least one
• a microwave is guided along the outer surface of the media-contacting standpipe.
• the device is specified according to the first aspect, wherein the first evaluation unit 1025 and the further evaluation unit 1026 are in parts or entirely substantially identical 1033.
• the device according to the first aspect or the second aspect is given, wherein the distance of the first
• the distance of the first level level and the further level level from the control device may be measured along a direction of propagation of the electromagnetic Wel le when emitting.
• the device is described according to one of the first to third aspects, which further comprises a unit 101 1, 1027, 1033 for determining at least one characteristic for the level and / or the position of a release layer and / or for has the composition of an emulsion, for which purpose the at least one first value and the at least one further value are used.
• the device is described according to the fourth aspect, wherein the first evaluation unit, the further evaluation unit and / or the unit for determining at least one characteristic value for the level in Tei len or are completely identical.
• the apparatus of any of the first to fifth aspects is further provided with an inner conductor 603, 704 guided within the media-contacting standpipe 605, 708, the inner conductor and the media-contacting standpipe forming a coaxial conductor.
• the device is specified according to the sixth aspect, wherein the first evaluation unit 1025 is executed, the
• the apparatus of any one of the first to seventh aspects further comprises at least one umlaut tube 706 surrounding the standpipe, said at least one ummaiitelungsrohr 706 the outer conductor of at least one further coaxial line 708 forms, said Further
• Evaluation unit is executed, the at least one characteristic value for a level, the separation layer or the emulsion using the to another one
• the first measuring device 703 may have two connections, one connected to the outer tube 706 and the other to the inner tube 705.
• the second measuring device 703 may have two connections, one connected to the outer tube 706 and the other to the inner tube 705.
• Measuring device 702 may have two ports, one connected to the inner tube 705 and the other to the rod 704.
• a connection may be a connection cable.

Landscapes

• Physics & Mathematics (AREA)
• Electromagnetism (AREA)
• Fluid Mechanics (AREA)
• General Physics & Mathematics (AREA)
• Thermal Sciences (AREA)
• Engineering & Computer Science (AREA)
• Power Engineering (AREA)
• Acoustics & Sound (AREA)
• Measurement Of Levels Of Liquids Or Fluent Solid Materials (AREA)
• Radar Systems Or Details Thereof (AREA)

Priority Applications (7)

Applications Claiming Priority (1)

Publications (1)

Family

ID=44515137

Family Applications (1)

Country Status (7)

Cited By (1)

Families Citing this family (25)

Citations (4)

Family Cites Families (15)

• 2010
  • 2010-12-16 RU RU2013132713/28A patent/RU2552573C2/ru active
  • 2010-12-16 CN CN201080070756.3A patent/CN103261852B/zh active Active
  • 2010-12-16 WO PCT/EP2010/069992 patent/WO2012079642A1/de active Application Filing
  • 2010-12-16 EP EP10795341.6A patent/EP2652462B1/de active Active
  • 2010-12-16 CA CA2819754A patent/CA2819754C/en active Active
  • 2010-12-16 BR BR112013014990-6A patent/BR112013014990B1/pt active IP Right Grant
• 2011
  • 2011-12-16 US US13/328,062 patent/US9046404B2/en active Active

Patent Citations (4)

Also Published As

Similar Documents

Legal Events